Automatic train control equipment



T. W. MASTERMAN AUTOMATIC TRAI'N CONTROL EQUIPMENT l. March 29, 1938.

Filed Aug. 29, 193e 5 Sheets-Sheet l mmv. sx1@ @T IPP-Pf@ @n.0 www v @ww hom. W

March 29, 1938. T. w. MAsTr-:RMAN 2,112,421v

' A- AUTOMATIC TRAIN CONTROL EQUIPMENT y Filed'Aug. 29, 195e 'Y 5 sheets-sheet 2 UME EsERvol RAKE PIPE IIII e, @sa ING RESERVOlR H7 |26 No.2. '30| ESQ PRESS! INVENTOR. THOMASWMASTERMAN ATTORNEY.

March 29, 1938. T. w. MASTERMAN AUTOMATIC TRAIN CONTROL EQUIPMENT 5 Sheets-Shee 3 Filed Aug. 29, 1956 ATTORNEY.

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acknowledging valve shown in Fig. 1, showing theconnections established thereby in the acknowledging position of the valve,

Fig. is a diagrammatic view in development form, showing the various pneumatic connections established by the upper rotary valve and the lower rotary valve of the brake valve device shown in Fig, l, for the various operating positions of the operating handle of the brake valve, and

Fig. 6 is a diagrammatic view in development form, showing the pneumatic connections established by the changeover valve of the bra-ke valve device shown in Fig. 1 when the changeover valve conditions the brake valve device for straight-air operation of the brakes and for automatic operation of the brakes.

The embodiment shown in Figs. 1, 2 and 3 taken together represents the equipment for only the control car of the train. However, it will be understood that portions of the equipment shown in Fig. 3 are duplicated on other cars of the train and are controlled and operated in the same manner as is the equipment shown in Fig. 3. Thus, for the purposes of the present application, the equipment will be treated as applying to one car only but it will be understood that the invention is intended to apply to the complete equipment for a train of cars.

Brief description of equipment Referring to Figs. 1, 2 and 3, the equipment shown comprises, briefly, a main reservoir l l and a so-called feed valve reservoir l2 which is charged with iluid under pressure through a feed valve i3, hereinafter designated feed valve No. l, the main reservoir ll being charged with fluid under pressure by a fluid compressor not shown. EX- tending throughout the train are a main reservoir pipe i4 charged with iluid under pressure directly from the main reservoir l l and a feed valve pipel5 charged with fluid under pressure from the feed valve reservoir I2.

An application valve device lli is provided for controlling the pressure in a brake pipe il which extends throughout the length of the train. The control car, as well as each of the other cars, not shown, is provided with one or more brake cylinders, such as the brake cylinder i9, the supply of fluid under pressure to which is under the control of a brake 'control valve device 2|, illustrated for simplicity as a triple valve device of well known construction. An auxiliary reservoir 22 is charged with fluid under pressure from the brake pipe il' in the usual manner upon an increase in brake pipe pressure under the control of theV valve device 2 l, and upon a reduction in brake pipe pressure the valvedevice 2l operated in well known manner to supply fluid under pressure from the auxiliary reservoir to the brake cylinder i3 to effect application of the brakes by so-called automatic operation.

A brake valve device 25 is provided which has a changeover valve device 25 adapted when in one position to condition the brake valve 2li to so control the application valve i6 as to effect application of the brakes by automatic operation. When the changeover valve device 2li of the brake valve it is in a second position, the brake valve 25 is conditioned so as to cause application of the brakes by straighten' operation, fluid under pressure being sup-plied under the control of the brake valve 225 and through a double check valve device 3Q to control. a selfelapping pneumatic switch 23. The pneumatic switch 28 'controls a magnet valve mechanism on each car, which in turn controls the supply of fluid under pressure from a supply reservoir 3l to a straight air pipe 32, the pressure in the brake cylinder l@ being controlled according to the pressure in the straight-air pipe 32.

rIhe application valve device l@ also functions to effect a train control application of the brakes either by straight-air or by automatic operation. dependent upon the changeover valve device fili of the brake valve device 25 being in straight-air or automatic position. A timing valve mechanism 3d, controlled by a track block signal responn sive apparatus hereinafter called the track signal apparatus and indicated in block form, functions to control the operation of the appliu cation valve device it to ca1 se train control applications of the brakes. A pair of reduction limiting reservoirs, l@ and 2li, hereinafter called No. I and No. 2 respectively, are associated with the application valve device iE, reduction limiting reservoir No. 2 being cut in or cut out of operation by .a manually operated valve i9! A suppression valve device 3l, controlled by brake valve E5, is operative to nullify the eifectiveness of the timing valve mechanism 34 to control the operation of the application valve iii, and thereby to suppress a train control application of the brakes, whether the brake valve device '25 is conditioned to effect manual control of the brakes by straight-air operation or by automatic operation.

A reduction insuring valve device 3u is provided which is operative, following the reception of a track block signal, only when a sufficient reduction has been effected in the brake pipe pressure incident to application of the brakes by manual automatic operation, to cause the suppression Valve device 3l to suppress a train control application. Upon an insuflicient reduction in brake pipe pressure, Yfollowing the reception of a track block signal, the reduction insuring valve 39 is not operative and consequently causes the suppression valve l' to be ineffective to continue to suppress a train control application of the brakes.

In order to prevent the opera-tion of the timing valve mechanism 3tlupon the reception of a train control or track block signal, 'without necessitating the application of the brakes by manual operation of the brake valve 225, I provide an acknowledging valve di. Acknowledging valve lli is normally in one position, shown in Fig. 1, for causing fluid under pressure to be supplied from the feed valve pipe l5 to a reservoir t2, hereinafter called acknowledging reservoir No. l and to a second reservoir fla, hereinafter called acknowledging reservoir No. 2. Upon operation of the acknowledging valve manually from the position shown in Fig. 1 to another or acknowledging position, shown in Fig. e, fluid under pressure is supplied from acknowledging reservoir No. l and acknowledging reservoir No. 2 to a pneumatic switch lll, hereafter called an acknowledging switch, which functions together with the track signal apparatus 35 to prevent the operation of the timing valve mechanism 3# resulting in a train control application of the brakes.

In order to prevent the operation of the acknowledging valve 4| from being effective to prevent the operation of the til/rung valve mechanism 35i to cause a train control application prior to the reception of a train control signal, I provide an acknowledging cut-ofi magnet valve device lo which is under the control of the track signal apparatus 35 and which, in the absence of a track block signal being received by the apparatus S5, is conditioned as shown in Fig. 1 so that if the Til effective to operate the acknowledging switch only after a train control signal has been received by the track signal apparatus 35. ,L

A pneumatic switch d, hereinafter called the interlock switch, is provided which is normally closed in series circuit relation with acknowledging switch 34. The interlock switch is actuated to circuit-opening position under the control of application valve device I E whenever the application valve device I6 is shifted to application position, in order to render the operation of the acknowledging valve device 4I ineffective to prevent a train control application of the brakes going through to completion once the train control application is initiated.

A suppression switch 45 is provided which is effective in cooperation with the track signal apparatus 55 to prevent the operation of the timing valve mechanism 34 to cause a train control application of the brakes if the train is stopped in a danger zone or at a station.

Associated with the timing valve mechanism is a timing reservoir 38, hereinafter designated the timing reservoir No. 2, which functions to delay the operation of the application valve i for a predetermined length of time, such as six seconds, from the time that a train control signal is received by the track signal apparatus and accordingly by the timing valve mechanism Thus the engineman has an interval of time after the reception of a train control signal within which to eifect a sufcient application of the brakes manually by operation of the brake valve device 25 or to operate the acknowledging valve fil and thus forestall or prevent the train control application of the brakes.

With the acknowledging valve 4I in the acknowledging position, shown in Fig. 4, fluid under pressure is sup-plied as previously stated to the acknowledging switch 44 to thereby prevent the operation of the timing valve mechanism resulting in a train control application of the brakes. in order to maintain the engineman on the alert, in the event that he chooses to operate the acknowledging valve to forestall a train control application of the brakes upon the reception of a train control signal instead of operating the brake valve 25 to effect manually either a straight-air or automatic application of the brakes, I provide a timing choke 49 through which the fluid supplied to the acknowledging switch it is vented to atmosphere. Thus, unless the engineman repeatedly returns the acknowledging valve to normal position to recharge the acknowledging reservoirs, he is unable to continue to forestall or suppress the operation of the timing valve mechanism 34 to cause a train control application of the brakes.

In order tc adapt the brake control equipment for use in connection with diiierent types of track signal systems which may exist on different divisions of the same railroad or on different railroads, I provide a system changeover valve device 5i which is effective in one position to cut in the timing reservoir No. I and acknowledging reservoir No. 2. When the system changeover valve device 5I is in a different position, the timing reservoir No. 2 and acknowledging reservoir No. ii are both cut out and thus the delay time between the reception of the train control signal by the track signal apparatus 35 and the operation of the application valve I5, as determined by the timing valve mechanism 3d, that is, the time within which the engineman may act to suppress the train control application" of the brakes is reduced, and also the frequency is increased with which the engineman must return the acknowledging valve to its normal position to recharge the acknowledging reservoir No. I and thus render the acknowledging switch M effective to forestall or suppress operation of the timing valve mechanism 3Q resulting in a train control application of the brakes.

A magnet valve device 52 which is controlled by a suitable switch mechanism, not shown, included in the track signal apparatus 35, serves to control the supply of fluid under pressure from the feed valve pipe I5 to the system changeover valve device 5I to cause the valve device to operate to one position or to the other position.`

The brake control equipment comprising my invention is adapted to function in connection with a so-called continuous or a so-called intermittent type of track signal system which may be employed on different railway systems or on 'different divisions of the same railroad. -Accordingly, the track signal apparatus 35 includes two diierent types of equipment (not shown) for translating track block signals to the moving train. In order to adapt the brake control equipment to function in connection with either type of translating equipment in the track signal apparatus 35, I provide a pneumatic changeover switch device 53 to connect one or the other of the translating equipments of track signal apparatus 35 for operation, the switch 53 being operatively controlled by the supply and the release of fluid under pressure thereto in the same manner as the changeover valve device 5I, under the control of the magnet valve device 52. Further equipment may be provided on every car of the train or on only certain cars of the train and includes a sander valve device 54 which is effective to control the charging of a sanding reservoir 55 from the feed valve pipe I6 and also the supply of uid under pressure from the sanding reservoir 55 to a sander device 56. Operation of the sander valve device 54 is effected under the control of the application valve device i6, the application valve i5 being effective to supply fluid under pressure to the sander valve device 54 to cause operation thereof to supply fluid under pressure to operate the sander 55.

Detailed description of equipment Referring in further detail to the drawings, the application valve ydevice I6 shown in Fig. 2 comprises a sectionalized casing 5I embodying a slide Valve device 52, an equalizing discharge valve device 53, a feed valve supply cut-off valve device 55 and an insuring valve device 55 for straight-air operation.

The slide valve device 52 comprises a piston 55 having a chamber 6T at one side thereof and a chamber @t at the opposite side thereof, the piston 55 having a stem 59 extending into the chamber 58 for operating a slide valve 'H therein on a seat iii. The slide valve chamber 68 is constantly charged with fluid under pressure from the feed valve pipe I5 through a pipe 12 and branch pipe 13, the chamber 61 being charged with fluid under pressure from the chamber 68 through a choke port 14 in the piston 66. A biasing spring 'I5 interposed in the chamber 61 between the casing and the face of the piston 66 urges the piston 56 in the left-hand direction into contact with a grooved stop shoulder 18, the slide valve 1| being correspondingly shifted into1 the normal position thereof as shown in Fig. 2. Upon a reduction in pressure of the "fluid in piston chamber S1, the piston 66 is shifted by the higher fluid pressure in chamber 68 in the right-hand direction into sealing engagement with a gasket seat E0, the slide valve 1| being correspondingly shifted to application position.

A volume reservoir 11 is provided for enlarging the capacity of the piston chamber 61 and is charged with fluid under pressure from the piston chamber 61 through a pipe and passage 'I9 which is connected to the timing valve mechanism 34 in the manner hereinafter described, and a branch pipe 19. Contained in the branch pipe 19 is a one-way or check valve 8| Which prevents flow of iiuid under pressure therepast into the volume reservoir 11 and permits free flow of fluid under pressure in the opposite direction as indicated by the arrow. By-passing the check valve 8| in the pipe 19 is a pipe 82 containing a restricted passage 83 through which fluid under pressure for charging the volume reservoir 11 may be supplied. The slide valve 1I contains various cavities or ports cooperating in the normal and application positions of the slide valve with Various atmospheric exhaust passages and other passages, which open at the seat 10, in a manner which will be subsequently made apparent.

The equalizing discharge Valve device 63 comprises a piston 91| having on one side thereof an equalizing piston chamber 85 to which an equalizing reservoir 86 is connected through a pipe and passage 81 and branch passage 88, and having at the opposite side thereof a brake pipe chamber 89 which is constantly open to the brake pipe I1 through a passage 9| and a passage and pipe 92. A discharge valve 93 is operated by the piston 84 through the medium of a stem 94 o-n the piston and is adapted when unseated to open communication between the brake pipe chamber 89 and a chamber 95 which is open to atmosphere through a pipe and passage 90 having a restricted passage 91.

The cut-off valve device '64 comprises two pistons 98 and 99, the piston 98 being slightly larger than the piston 99. The two pistons 98 and 99 are connected by a rigid stem Ii and there is a chamber |02 therebetween to which the brake pipe I1 is connected through the pipe and passage 92. Interposed between the chamber |02 and one face of the piston 98 is a chamber |03 which is open to the chamber |02 through a wide passage |04 and through a choke passage |95. The chamber |03 is supplied with fluid under p-ressure from the feed valve pipe I5, in the manner hereinafter described, through a pipe and passage |06 .which opens into chamber |03. At the outside face of the piston 98 is a chamber |01 which is normally connected to a chamber |98 at the outer face of the smaller piston 99, through a passage |09, a cavity III in the slide valve 1I and a passage ||2. The piston 98 fits loosely in the bore in which it operates and thus when iluid under pressure is supplied to the chamber |03 from the feed valve pipe I5 and passage |06, fluid underV pressure is supplied past the piston 98 into the chamber |01 and thence to the chamber |08 to substantially balance the fluid pressure forces acting on the pistons 98 and 99. A biasing spring I I3 interposed in the chamber |08 between the piston 99 and the casing, normally urges pistons 98 and 99 in the lefthand direction to the position shown.

When the slide valve 1| is shifted into application position, as hereinafter described, the cavity III in the slide valve connects the passage H2 to an atmospheric exhaust port ||4 to vent fluid under pressure from the chamber |08. The pressure of the fluid in the chamber |01 acting on the piston 98 thus becomes effective to overcome the tension of the spring ||3 and to thus shift both pistons in the right-hand direction to cause a gasket II5 carried on the right-hand face of the piston 98 to seat in sealing relation on an annular rib seat I|6 surrounding the passage |94, to cut 01T communication from the chamber |03 and the connected feed valve pipe I5 to the chamber |02 except through the choke passage |05.

The insuring valve device 65 of the application valve device I6 comprises a piston valve IIB operating in a bore ||9 in the casing 6I and normally Ybiased in the left-hand direction, to cause an annular gasket set in one face of the piston valve to engage an annular rib seat in the form of a bushing |20, by a biasing spring |2| interposed between the opposite face of the piston valve and the casing 6|. A pipe and passage |23, through which fluid under pressure is supplied in the manner hereinafter described upon a straight-air application of the brakes by operation of the brake valve 25, opens at the inner seated area of the piston valve I|8 within the bushing |20. At the outer seated area of the piston valve IIS is a chamber which is connected to an annular chamber |26 through a choke passage |21, the annular chamber |25 being connected to the brake valve device 25 through a pipe and passage |29. A chamber IBI at the right face of the piston valve II8 is constantly open to atmosphere through an atmospheric port |32 and is connected through a port |34 to the annular chamber |26 when the piston valve IIS is in seated relation on the annular rib seat |20.

When the pressure 0f the fluid supplied through the pipe and passage |23 to the inner seated area of the piston valve II8 is sufficient to overcome the tension of the spring |2I, which pressure may be of the order of forty pounds per square inch, the piston valve I I8 is shifted in the righthand direction to seat on a gasket and close o communication through the port |34 between the chamber I3I and the annular chamber |26. The piston valve II 8 is thus unseated from the annular rib seat or bushing |20, and communication is established through which fluid may iicw from the pipe and passage |23, through chamber |25, restricted passage |21, and annular chamber |29 to the pipe and passage |29. The functionof the insuring valve device will be brought out more clearly in connection with a hypothetical train control application of the brakes by straight-air operation to be described hereinafter.

The brake valve device 25 and its changeover valve device 25 are embodied in a unitary sectionalized casing I4I containing two chambers M3 and |04 which are constantly connected to and charged with fluid under pressure from the feed valve pipe |5 through a Vpassage and pipe |115 and, in the case of the chamber |43, also through a branch passage |46. Contained in the chamber |46 are two rotary valves |41 and |48, the valve |41 cooperating with a valve seat |49 on the casing and being designated hereinafter as the upper rotary valve. The valve |48 cooperates with a valve seat |5I on the casing and is hereafter designated the lower rotary valve. The two rotary valves |41 and |48 are adapted to be operated simultaneously by a rotary stem |52 which extends to the exterior of the casing ifll and has a squared end portion |53 at the end thereof for receiving a removable handle i 54.

The operating stem |52 has a cam |55 thereon which cooperates with the projecting stem |56 of a piston valve |51. The piston valve |51 operates slidably in a bore |58 and is yieldingly urged in the right-hand direction by a spring |59 interposed between the one face of the piston valve and a screw plug 16| which closes the open end of the bore |58, to cause an annular gasket |62 on the opposite face of the piston valve to engage an annular seat rib |63. The'piston valve |51 may either t loosely in the bore |58 or it may be provided with a pressure equalizing port |64 for preventing dash-pot action of the piston valve |51. The cam |55 on the operating stem |52 is so designed that only when the operating handle |54 is rotated to emergency position is piston valve |51 unseated from the annular rib seat |63 through themediurn of the stem |56 to connect a chamber |65 in the casing to atmosphere through a passage |66. As will be made apparent hereinafter, the piston valve |51 is effective to control operation of the equalizing discharge valve 63 of the application valve device |6 in case of automatic emergency application of the brakes effected by manual operation of the brake valve handle |54.

Contained in the chamber |44 is a rotary valve |66 which is operatively moved through the medium of an operating stem |1| having an exterior squared end portion |53a for receiving the removable handle 54. By providing only the one operating handle |54 which is normally carried on the squared end portion |53 of the operating stem |52, undesired and accidental shifting of the rotary valve |68 is guarded against.

As indicated in Fig. 6 the rotary valve |68 may be positioned in either of two positions, one of which is shown in Fig. l and indicated in Fig. 6 and which will hereinafter be called the straightairl position, and the other of which is merely indicated in Fig. 6 and which will hereinafter be called the automatic position. With the rotary valve 63 in its straight-air position, operation of the operating handle |511 of the brake valve 25 into service or emergency position causes application of the brakes by straight-air operation. With the rotary valve |68 in its automatic position, operation of the operating handle |54 to service or emergency position causes application of the brakes by automatic operation, that is, by controlling the pressure in the brake pipe I1.

Contained in the casing |4| of the brake valve device 25 are a plurality of passages |12, |13,

|15 and |16, one end of each passage opening at the valve seat |49 for the upper rotary valve l and the opposite end opening at the valve seat |69 for the rotary valve |68 of the changeover valve device 26. The passage |16 contains a choke |11 for a purpose which will hereinafter be made apparent.

Opening at the seat 5| of the lower rotary valve |48 are a plurality of ports and passages |19, |8|, |82, |83 and an atmospheric exhaust port |84. The passage |19 is connected to a pipe |19 leading to reduction limiting reservoir No. When the manually operable valve 30 is operated from the closed position shown, to the open position it establishes communication through a pipe |86 whereby the reduction limiting reservoir No. 2 is connected to the reduction limiting reservoir No. I. The function and the purpose of reduction limiting reservoirs No. and' No. 2 will be explained hereinafter. Connected to the pipe |86, between reduction limiting reservoir No. and the valve 30, is a pipe and passage |93 which opens at the seat 10 of the slide valve 1| of the application valve device I6, the passage |93 containing a choke |94 for a purpose which will be hereinafter made apparent.

The passage |8| is connected to a pipe and passage |8| which opens at the seat 1i) of the slide valve 1| of the application valve device |6.

The passage |82 leads to and opens at its opposite end at the seat |69 for the rotary valve |68 of the changeover valve device 26. The passage |83 opens into a passage and pipe |96 leading to and opening at the seat |619 for the rotary valve |68 and to the suppression valve 31 and suppression switch 46.

In addition to the ports and passages already mentioned which open atv the seat |69 of the rotary valve |68, a pair of ports and passages 20| and 263 and the passage and pipe |06 leading from the application valve device I6 open at the seat |69 and are connected in the straight-air position of the valve |68 by a passage 284 in the rotary valve |68. Passage 20| is connected by a pipe 26| to a branch pipe 205 opening out of feed valve pipe |5. The passage |06, as previously described, leads to the application valve device I6 and opens into the chamber |03 of the cut-orf device 64 thereof. The passage 203 is connected to a pipe and passage 203 which opens at the seat 10 of the slide valve 1| of the application valve device 6, the passage 263 being connected by a cavity 261 in the slide valve 1| to passage and pipe 81 leading to equalizing reservoir 86.

Also opening at the seat |69 of the rotary valve |68 are two passages 268 and 209 which are connected respectively to pipes 208 and 209 leading to different chambers in the double check valve 36 as will be described hereinafter. A passage and pipe 2|| opens at one end at the valve seat |69 of the rotary valve |68 and at the opposite end at the valve seat 10 for the slide valve 1| of the application valve device I6. The pipe and passage |29 which is connected at one end to the annular chamber |26 of the insuring valve device 65 of the application valve device I6 is open at its opposite end at the valve seat |69 of the rotary valve |68.

Also opening at the seat`|69 of the rotary valve |68 are an atmospheric exhaust port 2|2 and a port and passage 2|3, the purpose of which will be made clear hereinafter.

As will be seen in Figs. 1 and 5, the upper rotary valve |41 of the brake valve device 25 is provided with a cavity 2|5 which connects the three ports and passages |12, |13 and |14 in the release position of the operating handle |54, the ports and passages |15 and |16 being blanked at the seat |49 of the rotary valve |41.

The lower rotary valve |48 has a cavity 2|6 which, in the release position of the operating handle |54, connects the ports and passages |19, I 8| and |83 to the exhaust passage or port |84,

the port and passage |82 being blanked or closed at the seat 15| ci" rotary valve |48.

As will be seen by referring to Figs. l and 6, the rotary valve |68 is provided with a plurality of cavities 2|8, 219 and 22|, the cavity 2|8 being effective in the straight-air position of the rotary valve |63 to connect the passage |13 to the passage 268, the cavity 2|8 being effective in the straight-air position of the rotary valve |68 to connect the passage |82 to the passage |26, and the cavity 22| being eiective in the straight-air position of the rotary valve |68 to connect the passage 263 to the passage 2||. In addition to the passage 264, previously described which connects the passage 26| to the passages |66 and 263 in the straight-air position of the rotary valve 168, the rotary valve |68 is also provided with a passage 223 which, in the straight-air position of the rotary valve |68, connects the passages |12 and |15 to the atmospheric exhaust port 2|2.

The double check valve device 36 comprises a sectionalized casing 23| containing two double check valves 232 and 233 in the form of pistons which operate in bores 234 and 235 respectively. Each of the valve pistons 232 and 233 is provided with a stem 236, the two stems extending into a passage 236 joining the bores and being adapted to meet therein in end-to-end contact. At the side of the valve piston 232 opposite to the passage 236 is a chamber 231 to which is connected a pipe and passage 238, the passage 238 opening at the seat 16 of the slide valve 1| of the application valve device I6 and being supplied with uid under pressure from the slide valve chamber 68 through a port 239 in the slide valve 1! when the slide valve is in its normal position shown in Fig. 2. To the chamber or passage 236 of the double check valve device 36 are connected the pipe and passage 26S leading from the seat |66 of the rotary valve |68, and the pipe and passage |23 which opens at the opposite end at the inner seated area of the piston valve H8 of the insuring valve device 65 of the application valve device I6.

On the side of the valve piston 233 opposite to the passage 236 is a chamber 24| to which is connected the pipe and passage 269 leading from the seat |66 of the rotary valve |68, Surrounding the bore 235 is an annular chamber 242 Which is connected to the bore 235 at opposite ends through a plurality of ports 243.

To the chamber 242 is connected one end of a pipe 244, hereinafter called the control pipe, the opposite end of which pipe is connected to the self-lapping pneumatic switch 28.

The pressure of the fluid in the chamber 231 urges the valve piston 232 into seated relation cn an annular gasket 246 and at the same time causes the stem 236 on the valve piston 232 to engage the stem 236 on the valve piston 233 and shift the valve piston 233 into sealing engagement with an annular gasket 241. Communication is accordingly established from the pipe 268 and central passage 236 in the check valve 36 to the annular chamber 242 and control pipe 244. When the pressure of the fluid in the chamber 26| is suiciently greater than the pressure in the chamber 231 both valve pistons 232 and 233 are shifted upwardly, the valve piston 232 into sealing engagement with an annular gasket 248 and the valve piston 233 into sealing engagement with an annular gasket 248. In the latter position of the valve piston 233, communication from the pipe 268 and passage 236 to the annular chamber 242 and the control pipe 244 is cut off while communication is established from the pipe 269 to the annular chamber 242 and control pipe 244.

Timing valve mechanism 34 comprises a casing 253 containing a pneumatic valve device 254 and a magnet valve device 255. The pneumatic valve device 254 comprises a double beat valve 256 contained in a chamber 251 which is connected to the suppression valve device 31 through a passage and pipe 258, the valve 256' being operated by a piston 259 which has a pressure chamber 26| at one side thereof and an atmospheric chamber 262 at the other side thereof which is open to atmosphere through a port 266. On one side the double beat valve 252 has a luted stem 263 which extends into a chamber 264 to which the pipe 18 leading from the piston chamber 61 of the application valve device I6 is connected. A biasing spring 266 acts on the end of stem 263 through a flange 265 on a pin 2650l to yieldingly urge the valve 256 away from an upper valve seat 261 into seated engagement on a lower valve seat 268.

The opposite side of the double beat valve 256 has a fluted stem 269 which extends into the chamber 262, and carries a collar 21| fixed thereto, a spring 212 being interposed between the collar 21| and the piston 259 for yieldingly urging the stem 269 relative to the piston to seat the double beat valve 256 on its upper seat when the piston is in its upper position and for yieldingly permitting the relative movement between the piston 258 and the stem 268 after the double beat valve 256 is seated on the upper seat 261 to thus permit the upper edge of the piston 259 to engage in sealing relation on an annular gasket seat 213. A spring 286 interposed between the casing and the piston 259 yieldingly urges the piston downwardly to cause an annular rib 216 on the lower face of the piston to engage a gasket seat 215 in sealing relation when fluid under pressure is released from` the chamber 25|, the spring 266 being at the same time eiective to urge the double beat valve 256 away fromthe upper valve seat 261, to open communication from the chamber 264 to the chamber 251 and pipe and passage 258, and into seated engagement on a lower valve seat 268 to cut off communication between the chamber 251 and the atmospheric chamber 262. A passage 214 is provided Which connects the outer seated area of piston 259, when seated n gasket 215, with the atmospheric chamber 262. When the piston is in its upper position seated on the gasket seat 213, it closes the passage 214.

The supply and the release of fluid under pressure to and from the chamber 26| of the pneumatic valve device 254 is under the control of the magnet valve device 255. The magnet valve device 255 comprises a pair of oppositels7 seating valves 211 and 218 having fiuted stems 219 which meet in end-to-end contact within a chamber 28| intermediate the chambers 282 and 283 within which the valves 211 and 218 are respectively contained. An electromagnet 284 is eiective, when energized, to act through the medium of a plunger or stem 285 to shift the valves 211 and 218 into seated and unseated positions, respectively, against the force of a biasing spring 286 acting within the chamber 283 on the valve 218. When the electromagnet 284 is deenergized, the spring 286 is effective to yieldingly urge the valves 211 and 218 into unseated and seated positions respectively.

The chamber 282 is constantly connected to atmosphere through a passage 288 and a choke port 289. The chamber 283 is constantly charged with fluid under pressure from the main reser- Voir pipe I4 through a branch pipe 29 I ,a pipe 292, a feed valve device 293, hereinafter called feed valve No. 3 and a pipe 294. The feed valve No. 3 regulates the pressure suplied into the pipe 294 to any desired value, such as forty-five pounds per square inch. Another feed valve device 295 hereinafter called feed valve No. 2 functions to regun late to a certain uniform pressure; such as sixty pounds per square inch, the supply of iiuid under pressure from the main reservoir pipe I4 and pipes 29| and 292 to a pipe and passage 296, the passage 296 opening at the seat 10 of the slide valve 1I of the application valve device I6. The chamber 29| of the magnet valve device 255 is connected to the chamber 26| of the pneumatic valve device 254 by a passage 291 containing, in parallel relation, a choke passage 298 and a nonreturn or check valve 299 of the ball type.

The timing reservoir No. 2 is connected to or cut off from a pipe and passage 36| opening into the chamber 26| of the pneumatic' valve device 254, under the control of the system changeover valve device 5|, in the manner to be hereinafter more specifically described.

The check valve 299 enables rapid ow from the chamber 28| of the magnet valve device 255 to the chamber 26| and prevents reverse flow of fluid under pressure therepast, the rate of flow of fluid under pressure from the chamber 26| and its connected timing reservoir No. 2 being determined by the size of the choke passage 29S. Y

When the electromagnet 284 of the magnet valve device 255 is energized and the valves 211 and 219 are actuated to their seated and unseated positions respectively, as shown in Fig. 2, fluid' under pressure is supplied from the supply pipe 294 past the unseated valve 218 to chamber 28| and thence through the passage 291 past the check valve 299 and to chamber 26| and its connected timing reservoir No. 2, the pressureof the fluid in the chamber 26| being effective to,y seat the double beat valve 256 on its upper seat 261. When the electromagnet 284 of the magnet valve device 255 is deenergized and the valves 211 and 218 accordingly shifted to unseated and seated positions respectively by the spring 286, the supply of iiuid under pressure from the supply pipe 294 is cut off by the valve 213 and communication is established past the unseated valve 211 through which fluid under pre-ssure is vented from the chamber 26| and its connected timing reservoir No. 2 through the passages 3| and 291, choke passage 298, chamber 23|, chamber 282, passage 286 and choke port 289.

The suppression valve device 31 comprises a casing 382 having a chamber 363 containing a double beat valve 384 and constantly connected to a reservoir 305, hereinafter called the stop reservoir, through a pipe and passage 366. The double beat valve 394 has a fluted stem 391 which operates slidably in a bore 388 and extends into a chamber 309 to which the pipe and passage 259 from the timing valve mechanism is connected. A biasing spring 3|8, interposed in the chamber 39 between a screw plug 3I| closing the end of the chamber 309 and a collar or flange 3|2 xed to a slidable pin or stem 3I2a, yieldingly urges the double beat valve 304 normally in. the lefthand direction into seated engagement on a valve seat 3|3 and unseats the valve 304 from a valve seat 3I4 to establish communication through which uid under pressure, supplied into the pipe 258 under the control of the timing valve mechanism 34, may flow through the chamber 399,

bore 368, chamber 303, pipe and passage 36 to the stop reservoir 305.

The casing 302 of the suppression valve device 31 further contains a movable abutment, such as the diaphragm 3|6, which has a chamber 3I1 at one side thereof constantly connected through a branch pipe and passage 3|8 to the pipe |96, leading from the brake valve device 25 and hereafter designated the suppression pipe. At the opposite side of the diaphragm 3K6 is a chamber 3 I 9 which contains a follower 32 associated With the diaphragm 3|6 and a coil spring 322 which is interposed between the follower 32| and the casing 302 to yieldin'gly urge the diaphragm 3I6 in the left-hand direction.

When fluid under pressure is supplied to the chamber 3I1, through the suppression pipe |96 and its branch pipe 3| 8, in the manner to be hereinafter described, the diaphragm 3|6 is urged in the right-hand direction against the force of the spring 322, and a stem 323 of the diaphragm follower 32| engages in end-to-end contact the fiuted stem 324 of the double beat valve 394 and shifts the double beat valve 304 against the tension of the spring 3I0 into seated engagement with the valve seat 3|4 to cut off communication between the pipe 258 and the stop reservoir 305. At the same time, communication between the stop reservoir 305 and chamber 3I9 is established past the open valve seat 3|3 from which the double beat valve 304 is unseated.

Chamber 3|9 of the suppression valve device 31 is connected by a branch pipe 325 to a pipe and passage 326 which opens at the seat of the slide valve 1| of the application valve device I6 and which in the normal position of the slide valve 1| is connected to an atmospheric exhaust port 321 opening at the seat of the slide valve 1|, through a cavity 328 in the slide valve 1|. The pipe 325 contains a non-return or check valve 329 which permits flow of uid under pressure therepast only in the direction indicated by the arrow and which prevents reverse flow of fluid under pressure therepast from the suppression valve device 31 to the application valve device I6. A by-pass communication 33| around the check valve 329 contains a restricted passage 332 which permits flow of fluid under pressure from the stop reservoir 365 and the chamber 3I9 at a relatively low rate to the seat of the slide valve 1| and thence to atmosphere through the port Since uid under pressure is vented from the piston chamber 61 of the application valve device i6 and the connected volume reservoir 11 whenf ever the timing valve mechanism 34 is operated to establish communication past the valve seat 261 of the double beat valve 256, which reduction in fluid under pressure is effective to cause the piston 66 and its associated slide valve 1| kto be actuated in the right-hand direction to produce a train control application of the brakes in the manner to be described hereinafter, it Will be apparent that if the double beat valve 394 of the suppression valve device 31 is actuated into seated relation on the valve seat 3|4` to cut off the stop reservoir 395`from the pipe 258, then the reduction of pressure in the piston chamber 51 of the application valve device which is effected is insufiicient to acztuate the piston and slide valve in the right-hand direction to produce a train control application of the brakes.

The reduction` insuring valve device 39 comprises a casing 335 having a chamber 336 con- 385 and 386 into unseated and seated positions respectively, the chamber 39| and the connected pipe and passage 382 being accordingly vented to atmosphere past the unseated valve 385 and through the atmospheric passage 395, while the connection between the chamber 39| and the chamber 388 is cut off by the seated valve 386.

When the electromagnet 392 is energized and the valves 385 and 336 accordingly actuated to seated and unseated positions respectively, the connection from the vchamber 39| and the con n'ected pipe and passage 382 to the atmosphere is cut off by the seated valve 385 and communication is established from the chamber 39| past the unseated valve 386 to the pipe and passage 396 leading to the acknowledging switch 44. The acknowledging switch 44 may be of any suitable construction and is illustrated as comprising a casing 391 containing a piston 398 for actuating a contact bridging member 399 into engagement with a pair of stationary contact members 40| upon the supply of fluid under pressure from pipe 396 to a chamber 402 at one side of the piston 398. A biasing spring 403 acting within a chamber 404 at the opposite side of the piston shifts the piston so as to separate the contact member 399 from the contact members 40| when uid under pressure is released from the chamber 402. The tension of the spring 403 is such that a certainv low uniform degree of fluid pressure, such as two or three pounds per square inch, is suflicient to overcome the spring and move the piston to shift the contact member 399 into circuit-closing position.

The pipe 396 connecting the magnet valve device 45 and the acknowledging switch 44 has a branch pipe 406 connected thereto which is open to atmosphere through a choke passage 49.

The cooperative relation of the acknowledging valve 4| acknowledging cut-off magnet valve device 45 and the acknowledging switch 44 should now be clear. It will be seen that if the electromagnet 392 of the magnet Valve device 45 is deenergized, as it normally is with the equipment conditioned as shown, operation of the handle Sie of the acknowledging valve 4| to acknowledging position is merely effective to vent the uid under pressure from the acknowledging reservoirs No. and No. 2 to atmosphere through the pipe and passage 319, passage 38| in the rotary valve 312 of the acknowledging valve 4|, passage pipe 382, chamber 39| of the magnet valve device 45, pastthe unseated valve 305, through chamber 381 and passage 395. On-the other hand, if the' electromagnet 392 of the magnet valve device 45 is energized when the operating handle 315 of the acknowledging valve device 4| is operated to acknowledging position, fluid under pressure is supplied from the acknowledging reservoirs No. and No. 2 to the chamber 39| of the magnet valve device 45 as previously traced, and thence past the unseated valve 386 through chamber 398 and pipe 396 to the chamber 402 of the pneumatic acknowledging switch 44 to j actuate contact Amember 399 into circuit-closing position in engagement with the contact members 49|. However, since the pipe 396 and the connected chamber 402 of the acknowledging switch 44 is open to atmosphere through the choke passage 49, the pressure in the chamber 402 of the acknowledging switch 44 will, after a predetermined time which is dependent on the capacity of the acknowledging reservoirs No. and No. 2 and the size of the choke passage 49, suiciently reduce the pressure so that the biasing spring 403 of the acknowledging switch 44 effects separation of the contact member 399 from the contact members 40|. If it is desired, therefore, to maintainthe contact member 399 of acknowledging switch 44 in circuit-closing position, it is necessary to momentarily return the operating handle 315 of the acknowledging valve 4| to its normal position for effecting recharge of the acknowledging reservoirs No. l and No. 2, and then return the operating handle 315 to the acknowledging position again. It will be understood that the` acknowledging reservoirs No. and No. 2 may be recharged more rapidly than the pressure in the chamber 402 of the acknowlswitchflhican be reduced through choke 49 and therefore that it is possible by a so-called fanning or repeated operation of the operating handle 315 of the acknowledging valve device 4I to its normal charging position from the acknowledging position, to indefinitely maintain the acknowledging switch 44 in circuit-closing position.

As previously explained, the time interval which elapses from the reception of a track signal by the track signal apparatus 35 and the consequent d eenergization of the electromagnet 234 of. the magnet valve device 55 of the timing valve mechanism 34, to the operation of the pneu'- rnatic Valve device 254 to vent fluid under pressure from the piston chamber 61 of the applica.- tion valve device I6 to the pipe and passage 258 and eventually to the stop reservoir 305, is dependent upon the volume of the timing reservoir No. 2 and the size of the choke passage 298. Furthermore, as just described, the frequency with which the operator must return the operating handle 315 of the acknowledging Valve to its normal charging position from acknowledging position in order to maintain the acknowledging switch 44 in circuit-closing position depends upon the capacity of the acknowledging reservoirs No. and No. 2. If, therefore, it is desired to increase the frequency with which the operator must operate the operating handle 315 0I". the acknowledging Valve 4| in order to maintain the acknowledging switch 44 in circuit-closing position, the capacity of the acknowledging reservoir must be reduced.

In order, therefore, to provide for increasing the frequency of operation of the operating handle 315 of the acknowledging valve device 4| to maintain the acknowledging switch 44 in circuit-closing position and in order to reduce the time delay from the receptionl of a track signal by the timing valve mechanism 34 to the operation of the pneumatic valve device 254 thereof to vent iiuid under pressure to stop reservoir 305, I provide according to my invention, a system changeover valve device 5|.

The system changeover valve device 5| comprises a casing 409 containing a piston 4|| having a piston chamber 4|2 at one side thereof and a slide valve chamber 4|3 at the opposite side thereof. containing a slide valve 4|4 which is operative by movement of the piston 4| through the medium of a stem 4| 5 of the piston 4| The piston chamber 492 is supplied with uid under pressure through a pipe and passage 4|6 connected to the changeover magnet valve device 52, the magnet valve device 52 being operative to control the supply of iiuid under pressure from the feed valve pipe l5 to the pipe and passage 4|9 and the piston chamber 4|2 and the rrelease of fluid under pressure from the piston Vpresently described. The slide valve chamber 4 I 3 `is constantly connected to and charged with iiuid Vunder pressure from the feed valve pipe I5 through a pipe and passage 4|1 which is connected to the branch pipe 12 of the feed valve pipe I5.

`With equal uid pressures in chambers 4 I 2 and 4I3 on opposite sides of. the piston 4| I, a biasing spring 4|8, contained in the piston chamber 4|2 and interposed between the casing and the piston 47| I, urges the piston in the left-hand direction into engagement with a stop shoulder 4|9, the slide valve 4|4 being accordingly shifted into the position shown in Fig. 2 wherein a cavity 42| in the slide valve connects a pipe and passage 422 leading from acknowledging reservoir No. I to a passage and pipe 423 leading to acknowledging reservoir No. 2 and wherein a cavity 424 in the-slide valve 4|4 connects pipe and passage 33| which leads out of the piston chamber 26| of the pneumatic valve device 254 of the timing valve mechanism 34 to a pipe and passage 425 leading to timing reservoir No. 2.

Upon a reduction in the Vpressure in the piston chamber 4I2, the higher pressure in the slide valve chamber 4|3 shifts rthe piston 4|| in the right-hand direction against the tension of the biasing spring 4|9 into sealing engagement with a gasket 426, the slide valve 4I4 being accordingly shifted to a position in which the connection between acknowledging reservoir No. I and acknowledgingreservoir No. 2 is cut off and the connection between the venting pipe and passage 30| and the timing reservoir No. 2 is cut oi.

Changeover magnet valve device 52 comprises a pair oi oppositely seating valves 428 and 429 contained in chambers 43| and 432 respectively and having fluted stems 433 which meet in endto-end contact. An electromagnet 434 is provided which is effective when energized to actuate a plunger or stem 435 to engage the valve 428 and simultaneously shift the valves 428 and 429 to seated and unseated positionsrespectively against the force of a biasing spring 436 contained in the chamber 432 and acting on the valve 429. A chamber 431, intermediate the two chambers 43| and 432 and to which is connected the pipe and passage 4|6 leading from the system changeover valve device 5|, is supplied with uid under pressure past the unseated valve 429 from the chamber 432 which is constantly connected to the feed valve pipe I5 through the branch pipe 12.

When the electromagnet 434 is deenergized, spring 436 shifts the valves 428 and 429 to unseated and seated positions respectively. Valve 429 thus cuts off the supply of feed valve pressure from the chamber 432 to the chamber 431, and the valve 428 opens communication from the chamber 431 to the chamber 43| which is constantly open to atmosphere through an atmospheric passage 438.

Thus, when the changeover magnet valve device 52V is energized fluid under pressure is supplied from the feed valve pipe I5 to the piston chamber 4|2 of the changeover valve device 5| to operate it to the position shown wherein acknowledging reservoirs No. and No. 2 and timing reservoir No. 2 are cut in for operation. When the changeover magnet valve device 52 is deenergized, piston chamber 4| 2 of the changeover valve device 5| is vented to atmosphere and the slide valve 4|4 is accordingly operated to cut out of operation the acknowledging reservoir No. 2 and the timing reservoir No. 2.

The track signal apparatus 35 is provided for controlling automatically the energization and deenergization of the acknowledging cut-oil' magnet valve device 45 and the magnet valve device 255 of the timing valve mechanism 34 and ncludes manually operable switch mechanism (not shown) for controlling the changeover magnet valve device 52, electromagnet 284 of the magnet valve device 255 and electromagnet 434 of changeover magnet valve device 52 being connected to the track signal apparatus 35 by suitable pairs of wires as shown. As previously indicated, the track signal apparatus 35 includes two types of equipment which is responsive to the track block conditions. In the one type of track signal equipment known as the continuous type the acknowledging cut-off magnet valve device 45 is normally deenergized, the electromagnet 392 of the magnet valve device 45 being energized under the control of the track signal equipment only when a warning or stop signal is received by the ltrack signal equipment. In the other type of track signal equipment known as the intermittent type, this feature of preventing premature effective operation o-f the acknowledging valve device 4I is eliminated, and the electromagnet 392 of the magnet valve device 45 is accordingly required to be normally energized.

In order, therefore, toy establish suitable connections for energizing or deenergizing the acknowledging cut-off magnetvalve device 45 dependent upon which type of track signal equipment is employed, I provide a pneumatic type of changeover switch 53. The changeover switch 53 may be of any suitable construction and is i illustrated as comprising a casing 44| containing a piston 442 for actuating a pair of insulated contact members 443 and 444 into engagement with a pair of stationary contact members 445 and 446, respectively, through the medium of an operating stem 441. 'Ihe piston 442 has a chamber 448 at one side thereof which is constantly connected to the pipe 4 I 6 leading to the piston chamber 4|2 of the system changeover valve device 5| by a branch pipe 449. When uid under pressure is supplied to the piston chamber 4|2 of the changeover valve device 5| under the control of the changeover magnet valve device 52, fluid under pressure is thus also supplied to the chamber 448 of the changeover switch 53 and the contact members 443 and 444 are actuated into contact with the contact members 445 and 446 respectively. Contained in a chamber 45| at the opposite side of the piston 442 is a return spring 452 which is eiective to shift the piston downwardly, Whenever fluid under pressure is vented from the chamber 448, to separate the contact members 443 and 444 from the contact members 445 and 446 respectively, and to shift them into engagement with a pair of stationary contact members 453 and 454, respectively.

The movable contact members 443 and 444 are connected by wires 456 and 451 to opposite terminals of the electromagnet 392 of the magnet valve device 45. The stationary contact members 445 and 446 are connected by wires 458 and 459 respectively to the track signal apparatus 35. Stationary contact members 453 and 454 are connected by wires 46| and 462 respectively to opposite terminals of a suitable source of current such as the battery 463, the opposite terminals of the battery 463 also being connected to the track signal apparatus 35 by the Wires 46| and 462.

It will thus be seen that when the changeover switch 53 is actuated so that the contact members 443 and 444 engage the contact members 445 and 446 respectively, the electromagnet 392 of the magnet valve device is connected to the track signal apparatus 35 which is effective to cause energization of the electromagnet 392 only upon the reception of a warning or stop signal by the track signal apparatus. If the fluid under pressure is vented from the chamber 448 of the changeover switch 53 and the contact members 443 and 444 accordingly actuated into engagement with contact members 453 and 454, it will be seen that the electromagnet 3920i the magnet valve device 45 is connected directly across the terminals of the battery 463 and that it is accordingly maintained constantly energized.

The interlock switch 48 is similar in construction to the acknowledging switch 44 and comprises a casing 464 containing a piston 465 for actuating a movable contact member 466 through the medium of a stem 461 into engagement with a stationary contact member 468. At one side of the piston 464 is a chamber 469 which is constantly connected by a branch pipe 41| to the pipe 238 leading from the application valve device !6 to the double check valve device 39 and uid under pressure supplied to the chamber 469 from the pipe 238 moves the piston against the force of a spring 412 interposed in a chamber 413 at the opposite side of the piston and between the casing and the piston, so as to cause the movable contact member 466 to engage the contact member 468. When fluid under pressure is released from the chamber 469, in the manner hereinafter described, the spring 412 shifts piston 465 downwardly to effect separation of the contact member 466 from the contact member 468. The interlock switch 48 is connected in series relation with the acknowledging switch 44 to the `track signal apparatus 35 through suitable wires as shown and thus when the interlock switch 49 is in circuit-opening position the operation of the acknowledging switch to circuit-closing po sition is ineffective.

The suppression switch 46 is similar in construction to the acknowledging switch 44 and comprises a casing containing a piston 552 which is controlled according to the unbalance between the pressure of iiuid in a chamber 553 at one side thereof which is connected to the suppression pipe |96, and the tension of a biasing spring 554 contained in a chamber 555 at the opposite side thereof to actuate a movable contact member 556 into and out of engagement with a pair of stationary contact members 551. One of the contact members 551 is connected by a wire 558 to the wire 458 leading to the track signal apparatus 35, as by connection to the contact member 445 of the changeover switch 53. The other contact member 551 is connected by a Wire 559 to the track signal apparatus 35.

The circuit connections (not shown) of the suppression switch 46 through track signal apparatus 35 with the acknowledging switch 44 and interlock switch 49 are such that if, when a warning or stop signal is received by the track signal apparatus 35, the acknowledging switch 44 is immediately closed, the operation of the suppression switch 46 to circuiteclosing position is effective to maintain the magnet valve device 255 of timing valve mechanism 34 energized and thus suppress a train control application of the brakes in the manner to be hereinafter more fully described.

Referring to Fig. 3, the brake controlling valve device 2| is shown in the form of a triple valve of well known construction and details of construction therefore are not shown. Briefly, however, the piston chamber of the brake control valve device 2| is connected to the brake pipe |1 through a branch pipe 415, the auxiliary reservoir 22 is connected to the slide valve chamber of the brake control valve device 2| by a branch pipe 416, and the brake cylinder port of the brake control valve device 2| is connected vby a pipe 411 to one end of the double check valve 418, the opposite end of which is connected to the straight air pipe 32.

'Ihe double check valve 418 is of well known construction and comprises a valve piston 419 shiftable into two opposite positions in engagement with the gasket seats 48| and 482 respectively, to establish communication from the brake control valve 2| through the pipe 411 to the brake cylinder 9 when seated on the gasket 482 and to establish communication from the straight air pipe 32 to the brakel cylinder I9 when seated on the opposite gasket seat 48| as shown in Fig. 3.

The pressure Ain the straight-air pipe 32 is controlled by the magnet valve mechanism 29 which is of well known construction and which comprises an application magnet valve device 483 and a release magnet valve device 484. The application magnet valve device 483y comprises an application valve 485 which is contained in a chamber 486 constantly connected to the supply f reservoir 3| through a pipe 481 and branch pipe 488, the valve 485 being yieldingly urged intoy seated relation on its associated valve seat by a biasing spring 489 contained in the chamberl 466 and acting on the valve 485. An electromagnet 49| is effective when energized) to actuate a plunger or stem 492 to unseat the valve 485 to establish communication from the chamber 496 to a chamber 493 which is connected to the straight-air pipe 32 through a passage 494. The supply reservoir 3| is constantly connected to the brake pipe 1 and charged with fluid under pres sure therefrom through a portion of the pipe 481 containing a non-return or check Avalve 495 to prevent back flow of fluid under pressure from the supply reservoir tothe brake pipe.

The release vmagnet valve device 485 comprises a release valve 496 contained in a chamber 491 which is constantly connected to the straight-air pipe 32 through the passage 494, the valve 496 having a biasing spring 498 acting thereon inthe chamber 491 to yieldingly urge the valve toward an associated valve seat. An electromagnet 499 isV effective, when energized, to actuate a plunger or stem 50| into engagement with the valve 496 to unseat it against the force of the spring 498 to establish communication from the chamber 491 t0 a chamber 502 which is constantly connected to the atmosphere through a port 563. When the electromagnet 499 is deenergized, the spring 498 is eifective to seat the valve 496 and thus cut off communication from the chamber 491 and the connected straight-air pipe 32 to the atmospheric chamber 592.

Energization and deenergization of the magnet valve devices 483 and 484 is eiected under the control of the pneumatic switch device 28.

The pneumatic switch device 28 comprises a casing 595 containing a movable abutment such as the diaphragm 566, the diaphragm 586 having a chamber 501 at one side thereof to which the control pipe 244 leading from the double check valve 38 is connected, and at the opposite side thereof a chamber 598 which is connected to the straight-air pipe 32 b-y a branch pipe 509. The

diaphragm 506 is adapted to actuate a pair of movable contact members 5II and 5I2 into and out of Contact with stationary contact members 5| I a and 5I2a, respectively, according to the relation of fluid pressure in the chambers 501 and 538.

Stationary contact member 5| Ia is connected to a train wire l5|?. to which one terminal of the electromagnet 49| of the application magnet valve device 483 shown in Fig. 3 and corresponding electromagnets (not shown) on other cars are connected by a branch wire 5|4. The stationary contact member 5I2a is connected to a train wire 5| 5 to which is connected one terminal of the electromagnet 499 of the release magnet valve device 484 by a branch wire 5|6, corresponding terminals of the electromagnets of release magnet Valve devices 434 on other cars being similarly connected. 'I'he remaining terminals of the electromagnets 49| and 499 are connected to one 'terminal of a source of current such as the battery 5|1 in any suitable manner, as through a ground connection 5I8. The terminal of the battery 5|1 opposite to the grounded terminal is connected by a wire 5|9 to both of the movable contacts 5II and 5|2.

When fluid under pressure is supplied through the control pipe 244 to the chamber 501 in a manner Vto be described hereinafter, the diaphragm 506 is urged downwardly to separate the contact member 5|2 from the contact member 5|2a, and thus interrupt the circuit normally completed therethrough for energizing the release electromagnet 499. Release magnet 499 is thus deenergized. Upon a suilicient increase in the pressure of the chamber 501, the diaphragm 506 causes the contact member 5|I to engage the contact member 5| Ia and thus complete the circuit for energizing the application electromagnet 49|. As the pressure of the fluid, supplied from the supply reservoir 3| past the application valve 485 to the straight-air pipe 32, builds up through pipe 509 in the chamber 508, the diaphragm 506 is returned upwardly to effect separation of the contact member 5II from the contact member 5| la. This interrupts the circuit of the application electromagnet 49| and the further supply of fluid under pressure to the straight-air pipe 32 is cut off. Pressure in the chamber 501 and the chamber 508 are thus so balanced as to position the diaphragm v506 in a position to separate the contact members 5II and 5|2 fromv their associated contact members 5| Ia and 5|2a, accordingly interrupting the circuit for both the ap-plication electromagnet 49| and the release electromagnet 499. Consequently, the magnet valve mechanism 29 is conditioned to prevent both the supply of fluid under pressure to the straightair pipe and its release therefrom, so that the brakes are maintained applied according to the pressure supplied to the rbrake cylinder I9 from the straight-air pipe 32.

The sander valve device 54, one of which may be provided on each car, comprises a casing 52| containing a piston 522 having a piston chamber 523 at one side thereof to which is constantly connected the pipe and passage 326 leading from the application valve device I6. The sander valve device 54 further comprises a pair of oppositely seating valves 525 and 526 which are `contained in a chamber 521 constantly connected through a pipe and passage 523 to the sanding reservoir 55. The valve 526 has a iluted stem 529 extending into a chamber 53| which is constantly connected-through a branch pipe and sanding of lthe rails.

passage 532 to the feed Valve pipe I5, a biasing spring 533 contained in the chamber 53| acting on the end of the fluted stem 529 to yieldingly urge valves 525 and 526 into seated and unseated positions respectively. Communication is thus established from the feed valve pipe I5 through the pipe 532, chamber 53|, past the unseated valve 526, through chamber 521 and pipe and passage 528 to charge the sanding reservoir 55. Whenever fluid under pressure is supplied to the chamber 523 from the pipe 326, the piston 522 is actuated downwardly to shift the valves 525 and 526 to unseated and seated positions respectively. The valve 526, when seated, cuts off the charging communication for the sanding reservoir 55, and the valve 525 when unseated establishes communication from the chamber 521 to a chamber 535 which is constantly connected through a pipe and passage 536 to the sander device 56 so that the fluid under pressure from the sanding reservoir 55 may be discharged through the sander device 56 to atmosphere to cause A one-way or non-return valve 531 prevents back flow of fluid under pressure from the sander device 56 to the sander valve device 14 through the pipe 536.

OPERATION (a) Charging of the equipment Withl the operating handle |54 of the brake valve device 25- in release position, with the brake valve changeover valve device 26 in the straight-air position, and with the equipment otherwise conditioned as shown in Figs. l, 2 and 3, the equipment is charged with uid under .i

pressure from the main reservoir II.

The feed valve pipe I5 is charged with fluid under pressure from the feed valve reservoir I2 which is in turn charged with fluid under pressure from the main reservoir II through feed valve No. I, the pressure of the fluid as regulated by feed valve No. I being less than the pressure maintained in the main reservoir II, which may be of the order of one hundred and twenty to one hundred and thirty pounds per square inch. Fluid under pressure is supplied from the feed valve pipe I5 to the rotary valve chambers |43 and |44 of the brake Valve device 25 through the pipe ,and passage |45 and, in the case of the chamber |43, also through the branch passage |46.

With the acknowledging valve device 4I in its normal position shown in Fig. l, fluid under pressure is also supplied from the feed valve pipe I5 through vthe pipe and passage 205, acknowledgu ing valve 4|, pipe 319 to acknowledging reservoir No. I and thence by way of pipe and passage 422, cavity 42| in slide valve 4|4 of the system changeover valve device 5| and pipe and passage 423 to the acknowledging reservoir No. 2.

Fluid under pressure is also supplied from the feed Valve pipe I5 to charge the brake pipe I1, fluid flowing through the branch pipe 205, branch `pipe and passage 20|, cavity 204 in the rotary valve |68 of the changeover valve device 26, pass sage and pipe I 06, chamber |03 of the cut-off Valve device 64 of the application valve device I6, through the passage |04, chamber |02 and passage and pipe 92 to the brake pipe I1. The brake pipe chamber 89 beneath equalizing discharge piston 84 of the equalizing discharge valve device 63, being connected to the pipe and passage 92 through the passage 9|, is likewise charged to the same pressure as the brake pipe I1.

.lai

The cavity 204 in the rotary valve |68 of the changeover valve device 26 also connects the passage and pipe 20| to the passage and pipe 203 and communication is thus established for the charging of the equalizing reservoir 86 and equalizing chamber 85 of the equalizing discharge valve device 63 by way of pipe and passage 203, cavity 201 in the slide valve 1I of the application valve device I6, passage and pipe 81 to the equalizing reservoir 86, and branch passage 88 to the equalizing chamber 85.

Feed valve pressure supplied to the chamber |03 of the cut-off valve device 64 leaks past the loose fitting piston 98 into the chamber |01 and thence to the chamber |08 at the outer face of the piston 99 through the passage |99, cavity III in the slide valve 1| of the application valve device I6, and passage ||2.

Chamber 353 of the reduction insuring valve device 39 is charged with fluid under pressure from the feed valve pipe I5 through the branch pipes 285 and 354 while the chamber 349 of the reduction insuring valve device 39 is charged with fluid under pressure from the brake pipe I1 through the branch pipe and passage 35|, the pressures on opposite sides of the diaphragm 352 thus being substantially balanced and the insuring valve being conditioned to connect the pipe 2I3 to atmosphere through the atmospheric port 344.

Fluid under pressure is also supplied from the feed valve pipe I5 through the branch pipes 12 and 13 to the slide valve chamber 68 of the application valve device I6 and through the choke port 14 in the piston 66 to the piston chamber 61 and thence through pipe .and passage 18 to the chamber 264 of the timing valve mechanism 34 and through the branch pipe 19, by-pass communication 82, and restricted passage 83 to the volume reservoir 11. When the pressure in the piston chamber 61 and slide valve chamber 68 on opposite sides of the piston 66 are substantially equalized, the biasing spring 11 is` effective to shift the piston 66 to the position shown wherein the port 239 in the slide Valve 1I registers with the pipe and passage 238 and thus establishes communication for' the supply of fluid under pressure from the slide valve chamber 68 through the port 239 and passage and pipe 238 to the interlock switch 48 and chamber 231 of the double check Valve device 30. The interlock switch 48 is accordingly actuated to circuit-closing position and the valve pistons 232 and 233 of the double check valve 30 shifted downwardly to the position shown.

With the changeover magnet valve device 52 energized, uid under pressure is supplied to the piston chamber 4|2 of the system changeover valve device 5I from the branch pipe 12 of feed valve pipe 5, chamber 432 of the changeover magnet valve device 52, past the valve 429, through chamber 431 and passage and pipe 4|6. At the same time, fluid under pressure is supplied from the pipe 4|6 to the chamber 448 of the changeover switch 53 to shift the contact members 443 and 444 into contact with the stationary contact members 445 and 446 as shown. The slide valve chamber 4 I 5 of the piston changeover valve device 5I is constantly charged with fluid under pressure from the feed valve pipe I5 by way of the branch pipes 12 and' 4|1. With the fluid pressures in chambers 4|2 and 4|3 on opposite sides of the piston 4| I thus` substantially equalized, the biasing spring 4I8 is effective to shift the piston 4|I, and the slide valve 4I4 to the position shown.

The sanding reservoir 55 is charged with fluid under pressure from the feed valve pipe I5 under the control of the sander valve device 54 in the manner previously described. The supply reservoir 3| is charged with fluid under pressure from the brake pipe I1 through the pipe 481 containing the check valve 485, and the auxiliary reservoir 22 is charged with fluid under pressure from the brake pipe by Way of the branch pipe 415 under the control of the brake control valve device 2|.

Fluid under pressure is also supplied from the main reservoir pipe I4 to the piston chamber 26| of the pneumatic valve device 254 of the timing valve mechanism 34 through branch pipes 29| and 292, feed Valve No. 3, pipe 294, chamber 283 of the magnet valve device 255 past the unseated valve 218, chamber 28|, passage 291, past the check valve 299, and through passage 39|. The piston 259 of the pneumatic valve device 254 is accordingly shifted upwardly to seat the `clouble beat valve 256 on its upper seat 261 as shown, and the timing reservoir No. 2 which is connected to the piston chamber 26| through the pipe and passage 38|, cavity 424 in the slide valve 4|4 of the system changeover valve device 5I, and pipe and passage 425, is simultaneously charged.

Fluid under pressure is also supplied from the main reservoir pipe I4 through the branch pipes 29| and 292, feed valve No. 2 to the pipe and passage 296 opening at the seat of the slide valve 1| of the .application valve device I6. However, passage 296 is lapped by the slide valve 1| in the normal position of the slide valve.

'I'he brake cylinder I9 is connected to atmosphere as shown through the double check valve 418, straight-air pipe 32, passage 494 of the magnet valve mechanism 29, chamber 491 past the unseated release valve 496, chamber 502 and exhaust port 583. v

(b) Manual straight-air operation of the brakes With the equipment conditioned as shown in Figs. 1, 2 and 3 and charged with fluid under pressure in the manner just described, a straightair application of the brakes may be effected by turning the operating handle |54 of the brake valve device 25 from the release position to the service position.

As will be seen in Fig. 5, with the operating handle |54 of the brake valve device 25 in service position, the upper rotary valve |41 is eiective to connect the passages |14, |15 and |16 through a cavity 58| therein and also connects the rotary valve chamber |43 to the passage |13 through a port 582. At the same time, the lower rotary valve |48, in the service position of the operating handle |54, is positioned to connect pipe and passage |19, leading from the reduction limiting reservoir No. to the atmospheric exhaust port |84 thro-ugh a cavity 583 therein and to connect the rotary valve chamber |43 to the port and passage |83 through a port 584 to supply fluid under pressure to chamber 3|1 of the suppresv sion valve device 31 and toy chamber 553 of the suppression switch 46.

Fluid under pressure is accordingly supplied from the rotary valve chamber |43 through the port 582 in the upper rotary valve |41, passage |13, cavity 2|8 in the rotary valve |68 of the changeover valve device 26, passage and pipe 208, passage or chamber 236 in the double check valve device 35, annular chamber 242 and control pipe 244 toi the chamber 551 of the pneumatic switch device 28. Fluid under pressure also flows from the passage 236 of the double check valve device 3U through the pipe and passage |23 to the inner seated area of the piston valve 8 of the insuring valve device 65 in the application valve device I5.

The pneumatic switch device 28 accordingly operates to control the energization and deenergization of the application and release magnet valve devices 483 and 484, in the manner previously described, to cause fluid under pressure to be supplied from the supply reservoir 3| to the brake cylinder |9 to effect application of the brakes, the degree of brake cylinder pressureattained corresponding to that attained in the straight-air pipe 32 which is in turn determined according to the pressure in the control pipe 244 and chamber 501 of the pneumatic switch device 28.

Fluid under pressure supplied to the suppression valve device 31 and to suppression switch 45 merely causes ineffective operation thereof at this time, the function and purpose of the su ipression valve device and switch being made clear hereinafter in connection with a train control application of the brakes to be hereinafter described.

When the desired degree of application of the brakes is attained, the operator returns the operating handle |54 of the brake valve device 25 to lap position wherein the supply of fluid under pressure from rotary valve chamber |43 to passage |13 through port 582 is cut off at the seat of the upper rotary valve |41 and wherein a cavity 585 in the upper rotary valve |41 connects the passage |14, which is lapped at the seat of the rotary valve |58 of the changeover Valve device 26, to the passage |15 which is connected through the cavity 223 in the rotary valve |68 to the exhaust port 2|2.

At the same time, with the operating handle |54 of the brake valve device 25V in lap position, the lower rotary valve |48 connects they passage |82 to the passage |83 through a cavity 586 therein. The purpose of this connection will be made clear in connection with a train control application of the brakes to be described later.

For present purposes, the effect of returning the operating handle |54 of the brake valve device 25 to lap position is to cut olf the supply of fluid under pressure from the rotary valve chamber |43 to the passage |13 leading to the double check valve 30 and the control pipe 244.

The pressure in the control pipe 244 and chamber 501 of the pneumatic switch device 28 may be increased in steps to graduate the application of the brakes, or the pressure in the control pipe and the chamber 551 may be increased as desired for increasing the degree of application of the brakes, by returning the operating handle |54 from lap position to service position and upon the attainment of the desired degree of application of the brakes returning the handle again to lap position. With each increase in the pressure of the fluid in chamber 501, the pneumatic switch device 28 functions to supply uid under pressure from the supply reservoir 3| to the straight-air pipe 32 and accordingly to the brake cylinder IS to a degree corresponding to the increase in the pressure in the chamber 581.

The maximum degree of application of the brakes for straight-air operation is attained when the pressure in the control pipe 244 and chamber 551 of the pneumatic switch device 28 is built up to full feed valve pipe pressure, it being impossible to further increase th-e pressure in the control pipe 244.

Release of the brakes following a straight-air application thereof, effected in the manner just described, is effected by returning the operating handle |54 to release position. The. upper rotary valve |41 and the lower rotary valve |43 are thus positioned as shown in Fig. 1 wherein the cavity 2|5 connects passage |13 to the passage |12 which is connected to the exhaust passage 2| 2 through cavity 223 in the rotary valve |68 of the changeover valve device 26.

Fluid under pressure is accordingly vented from the chamber 501 of the pneumatic switch device 28 by way of the control pipe 244, double check valve device 35, pipe and passage 258, cavity 2|B in the rotary valve |58 of the Vchangeover valve device 2G, passage |13, cavity 2|5 in the upper rotary valve |41, passage |12, cavity 223 in the rotary valve |68 and exhaust port 2 I2.

The pneumatic switch device 28 is accordingly actuated by the higher pressure in the chamber 508 to effect reengagement of the Contact members 5|?.k and 5|`2a and the separation of the ccntact members 5| and 5l la to respectively effect energization of the release magnet valve device 484 and deenergization of the application magnet valve device 483. Fluid under pressure is accordingly vented from the brake cylinder I9 by way of the double check valve 418, straight-air pipe 32, release valve 495, and exhaust port 553, the pressure in the chamber 588 of the pneumatic switch device 28 correspondingly reducing. When the pressure in the chamber 5538 of the pneumatic switch device 28 decreases slightly below the pressure in the chamber 501, the diaphragm, 555 is actuated downwardly to effect interruption of the circuit of both the application and release magnet valve devices 483 and 484 and the consequent lapping of the brakes.

When the desired degree of reduction in the brake application has been made the handle |54 of the brake valve device 25 is returned to lap position wherein the passage |13 is lapped at the seat |49 of the upper rotary Valve |41 and further reducticn in the pressure in the control pipe 244 and chamber 501 of the pneumatic switch 28 is stopped. Accordingly the brakes remain applied according to the degree of pressure maintained in the control pipe 244.

The degree of application of the brakes may be reduced in steps by successively moving the operating handle |54 of the brake valve device 25 to release` position and, after the desired degree in reduction of the application is attained, returning the operating handle to lap position.

Complete release of the brakes is effected by returning the operating handle |54 to release position and allowing it to remain there, fluid under pressure being accordingly completely vented from the control pipe 244 whereby the pneumatic switch device 28 is operated to cause complete venting of iuid under pressure from the brake cylinder I9.

(c) Manual automatic service operation of the brakes If the engineman desires to effect application of the brakes manually by automatic operation, that is, by varying the pressure in the brake pipe l1, he shifts the handle |54 of the brake valve device 25 to the exterior end of the operating stem of the changeover valve device 26 and rotates the rotary valve |68 into the automatic position thereof, after which he returns the operating handle |54 to the exterior end portion |53 of the operating stem |52. As will be seen in Fig. 6, in the automatic position of the brake valve changeover valve device 25, the

rotary valve 68 is positioned so that a cavity 588 therein connects the passage |14 to the passage 283, a passage 589 therein connects the passage |13 to the passage 28|, and a cavity 58| connects the passage |86 to the passage |12. The rotary valve |68 is also provided with a cavity or passage 592 which is effective in the automatic position of the rotary valve |88 to connect the passages |29, |16 and 288 to the exhaust port and passage 2|2, the rotary valve |68 being further provided with a cavity 593 which, in the automatic position of the rotary valve |68, connects passage |98 to the passage 2|3. In the automatic position of the rotary valve |58, the passages |15, |82, 289 and 2|| are lapped at the seat of the rotary valve.

In the automatic position of the rotary valve |69, different communications are established through which the brake pipe I1, the equalizing chamber 85, and equalizing reservoir 86 are charged with fluid under pressure from the feed valve pipe I5, compared to the charging communicaticns, previously described, for the rota-ry valve |58 in straight-air position. With the rotary valve |68 in automatic position, the equalizing chamber 85 of the equalizing discharge valve device 53 and the equalizing reservoir 88 are charged with fluid under pressure from the feed valve pipe I5 through branch pipe 285, pipe and passage 28|., passage 589 in the rotary valve |58, passage |13, cavity 2I5 in the upper rotary valve |41 of the brake valve device 25, passage |14, cavity 588 in the rotary valve |88, and thence through the passage and pipe 283, cavity 281 in the slide valve 1| of the application valve device I6 and passages 81 and 88. The charging communication for the brake pipe l1 is established from the feed valve pipe I5 to the cavity 2|5 in the upper rotary Valve |41 of the brake valve device 25 in the manner just described, and thence through passage |12, cavity 59| in the rotary valve |58, the passage and pipe |86 leading to chamber |83 of the cut-off valve device 54 of the application valve device I6, and thence to the brake pipey |1 in the manner described previously.

With the rotary valve |58 of the changeover valve device 26 in automatic position and the equipment charged with fluid under pressure as just described, an automatic service application of the brakes is effected manually by operation ofthe operating handle |54 of the brake valve device 25 to service position wherein the upper rotary valve |41 and the lower rotary valve |48 establish the same connections at the seats thereof as previously described for oper-ation of the operating handle to service position in a straightair application of the brakes.

The port 552 in the upper rotary valve |41 is positioned to connect the passage |13, which is supplied with fluid under pressure from the feed valve pipe l5 as previously described, to the rotary valve chamber |43 to assist in maintaining the pressure therein, while the passage |14 is connected by the passage 58| in the upper rotary valve |41 with the passages |15 and |18 leading to the seat |59 of the rotary Valve |68.

from the passage |14 to the passage |15 is without effect. However, the connection from the passage |14 to the passage |15 establishes a communication through which fluid under pressure from the equalizing reservoir 88 and from the equalizing chamber 85 of the equalizing discharge valve device 83 is vented to atmosphere, fluid flowing from the equalizing reservoir and equalizing chamber through the passage 81, cavity 281 in the slide valve 1|. of the application valve device i8, passage and pipe 283, cavity 588 in the rotary valve |88 of the changeover valve device 28, passage |14, passage 58| in the upper rotary v-alve |41, passage |16, including the choke |11 therein, and passage 592 in the rotary valve |58 to the atmospheric exhaust port and passage 2|2. The passage |12 is lapped at the seat of the upper rot-ary valve |41 and consequently the supply of fluid underv pressure from the feed valve pipe therethrough to the brake pipe is cut olf.

The choke |11 in the passage |18 is so designed as to restrict the rate of reduction of the pressure in equalizing reservoir 85 to the usual service rate of reduction. Upon the reduction of pressure in equalizing chamber 85 above the equalizing piston 84, the higher brake pipe pressure in the chamber 89 beneath the piston 84 shifts the piston upwardly into sealing Contact with a gasket 88 and thus unseats the discharge valve 98 to open communication from the chamber 85 to the chamber 95, from which fluid under pressure is discharged to atmosphere at a restricted rate through the choke 91 and pipe 95, which may lead to a point near the operator so that the discharge of air therefrom may serve as an indication to the operator of the proper functioning of the equalizing discharge valve device 63.

Due to the choked passage 91 restricting the rate of ow of fluid from the chamber 95 to atmosphere, the pressure in the brake pipe chamber 89 and the brake pipe I1 causes a build-up of pressure in the passage and pipe M8, part of the fluid under pressure discharged past the discharge valve 93 thus being supplied through the pipe 2|3 past the check valve 38| and to atmosphere by way of the branch pipe 888 leading to the reduction insuring valve device 88, choked passage 339, chamber 338, past the open valve seat 358, through the bore 342, chamber 843 and out through the exhaust port 844. Due to the restriction of the choke passage 539, pressure is built up in timing reservoir No. `connected through branch pipe 354 to the pipe 2|3 just beyond the branch pipe 338, the choke passage 885 in the pipe 2|3 just beyond the branch pipe 384 further' assisting in the build-up of pressure in the timing reservoir No.

Fluid under pressure is also supplied into the pipe 2|8 from rotary valve chamber |83 through port 584 in lower rotary valve |48 of brake valve device 25, passages |83 and |85, and cavity 593 in rotary valve |88, to assist in building up pressure in timing reservoir No. l, the choked passage 385 being eifectiv-e to cause substantially immediate build-up of fluid under pressure in the suppression pipe and passage |85 leading to the suppression valve device 81 and the suppression switch 45.l

The purpose and the effect of the supply of fiuid under pressure to timing reservoir No. and to the suppression valve device 31 and suppression switch 48 in the manner just described will be made apparent hereinafter in connection with a train control application of the b-rakes, there being no effective results produced thereby for the operation now being described, except that the discharge of fluid under pressure through the pipe 2I3 assists in the discharge of fluid under pressure from the brake pipe I1.

The equalizing discharge valve device 63 functions to reduce the pressure in the brake pipe in the manner similar to that of the equalizing discharge valve of the well known type of automatic brake valve, that is, the rate of reduction in brake pipe pressure I1 corresponds to the rate of reduction in equalizing reservoir and equalizing chamber pressure. Since the choke |11 restricts the rate of reduction in the equalizing reservoir and equalizing chamber pressure to a service rate, it follows that the brake pipe pressure is reduced at a service rate when the operating handle |54 of the brake valve device 25 is in service position. Upon the reduction in the pressure in the brake pipe I1 at a service rate, the brake control valve device 2| functions in the usual well known manner to supply fluid under pressure from the auxiliary reservoir 22 through the pipe 11 to the double check valve 418, where it acts to shift the valve piston 419 to the seat 482, if not already in such position, and establish communication through the double check valve 418 to the brake cylinder I6.

When the desired degree of service application of the brakes has been effected, the operator returns the operating handle |54 of the brake valve device 25 to lap position wherein the connection between the passages |14 and |16 is cut off at the seat of the upper rotary valve |41. Further reduction in equalizing reservoir and equalizing chamber pressure'is thus stopped and the equalizing discharge valve device 63 accordingly operates to seat the discharge valve 93 and cut off further reduction in the brake pipe pressure. The brake control valve device 2| accordingly operates in the well known manner to lap position to maintain the pressure in the brake cylinder I9 at the degree determined by the degree of reduction in the brake pipe pressure.

An increased degree of service application of the brakes may be eected by again turning the operating handle |54 of the brake valve device 25 to service position to effect a further reduction in brake pipe pressure and, when the desired increase in the degree of application of the brakes is attained, returning the operating handle to lap position. 'I'he maximum or full service application of the brakes is attained when the brake pipe pressure is suiciently reduced that the pressure in the auxiliary reservoir 22 equalizes with the pressure in the brake cylinder I9.

Following a service application of the brakes effected in the manner just described, a partial release of the brakes may be effected by turning the operating handle I 54 from lap position to release position to establish the communications, previously described, for building up the pressure in the brake pipe I1, the equalizing reservoir 86, and equalizing chamber 85. The brake control valve device 2| accordingly functions in the usual manner to charge the auxiliary reservoir 22 accordingly and release fluid under pressure from the brake cylinder I9.

When the desired degree of reduction in the degree of application of the brakes has been effected, the operator returns the operating handle |54 of the brake valve device 25 to lap position to cut oi the further increase in pressure in the brake pipe, equalizing reservoir and equalizing chamber.

A graduated release may be effected by turning the operating handle |54 of the brake valve device 25 repeatedly, in succession, from the lap position to the release position and back to lap position again.

Corn-plete release of the brakes is effected by returning the operating handle |54 to release position and allowing it to remain there, the brake pipe I1, equalizing reservoir and equalizing chamber being accordingly fully charged again in the manner previously described. The brake control valve device 2| is accordingly operated upon the restoration of the brake pipe pressure to its normal pressure to fully charge the auxiliary reservoir 22 and completely release uid under pressure from the brake cylinder I9 to effect complete release of the brakes.

(d) Manual automatic emergency operation of the brakes Let it be assumed that the. train is traveling along the tracks with the brakes released, the brake control equipment being conditioned as shown in Figs. l, 2 and 3 except that the rotary valve |68 of the brake valve changeover valve device 26 is in automatic position and that the operator desires to effect manually an automatic emergency application of the brakes. To do so, the operator turns the operating handle |54 of the brake valve device 25 to emergency position in which the cam |55 on the operating stem |52 is effective to unseat the piston valve |51 to vent the passage |12 to atmosphere through the exhaust passage |66 at the brake valve. As will be seen in Fig. 5, with the brake valve handle |54 in emergency position, the upper rotary valve |41 of the brake valve device 25 is positioned to connect the passage |12 to the passage |14 through a cavity 625 in the rotary valve, and to connect the rotary valve chamber |43 to the passage |13 through a port 626 in the rotary valve. With the brake valve handle |54 in emergency position, the lower rotary valve |48 is positioned to connect the rotary valve chamber |43 to the passage |83 through a port 621, and the other passages opening at the seat of rotary valve |48 are lapped (Fig.

Since the passage |12 is connected through cavity 59| in the rotary Valve |68 to the passage and pipe |06 through which the brake pipe is charged, and since the passage |14 is connected through the cavity 588 of the rotary valve |68 to the passage and pipe 203 through which the equalizing reservoir 86 and equalizing chamber 85 of the equalizing discharge valve device 63 are charged, it will be apparent that the unseating of the piston valve |51 of the brake valve device 25 will cause fluid under pressure to be simultaneously vented through exhaust port |66 from the edualizing reservoir, the edualizing chamber and the brake pipe.

The equalizing discharge valve device 63 of the application valve device I6 accordingly operates in the manner previously described for an automatic service application of the brakes, to vent fluid under pressure from the brake pipe I1 to the discharge chamber 95 and thence to atmosphere partly through choke 91 and pipe 96 and partly through the passage and pipe 2 I3, the total rate of reduction in brake pipe pressure being at an emergency rate.

With the brake valve handle |54 in emergency position the lower rotary valve |48 is positioned to connect the rotary valve chamber |43 to the passage |83 to supply iiuid under pressure to the suppression valve device 3l and suppression switch 45, and also to the pipe 2|3 to assist in charging the timing reservoir No. I, in the same manner as previously described for a service application oi the brakes. As in the case of the service application of the brakes, the supply of iluid under pressure to the suppression valve device 37 and suppression switch 46, as well as the charging of the timing reservoir No. is

` without productive effect in the present instance.

Upon a reduction in brake pipe pressure at an emergency rate, the brake control valve device 2| functions in the usual manner for an emergency application of the brakes to supply fluid under pressure from-the auxiliary reservoir 22 to the brake cylinder |9.

Release of the brakes following an automatic emergency application of the brakes manually effected as just described, is effected by return-n ing the operating handle |54 of the brake valve device 25 to release position wherein the piston valve |51' is reseated and the communications, previously described, are established to cause charging of the brake pipe, equalizing chamber and equalizing reservoir. Restoration of brake pipe pressure to the normal pressure causes operation of the brake control valve device 2| in the usual manner to effect recharging of the auxiliary reservoir 22 and complete venting of fluid under pressure from the brake cylinder.

(e) Adequate manual application of the brakes by straight-air causing suppression of train control application Let it be assumed that the train is travelling along the track with the equipment conditioned as shownin Figs. 1, 2 and 3, the rotary valve |68 of the changeover valve device 26 being in straight-air position and the operating handle |54 of the brake valve device 25 being in release position with the brakes completely released, a warning or stop signal is received by the track signal apparatus 35. The operator is immediately informed of the reception of the signal by audible and visible indicating means (not shown) included in the track signal apparatus and, under the control of the track signal apparatus 35, the electromagnet 284 of the magnet valve device 255 of the timing valve mechanism 34 and the electromagnet 392 of the acknowledging cut-off magnet valve device are automatically deenergized and energized respectively.

Upon the deenergization of the magnet valve device 255 of the timing valve mechanism 34, the communication is established through which iiuid under pressure is vented from the piston chamber 26| of the pneumatic valve device 254 of the timing valve mechanism 34 and the timing reservoir No. 2 connected to the chamber 25 iiuid flowing from the timing reservoir No. 2 and chamber 25| through the passages 38| and 292, choke passage 298, passage 29l, chamber 28| of the magnet valve device 255, past the unseated valve 2H, chamber 282, passage 288 and choke port 289. However, due to the size of the choked passage 258, it requires a. definite interval of time for the pressure in the chamber 25| to reduce sufiiciently so thatA the spring 28|] may become eiective to shift the piston 259 downwardly into engagement with the gasket seat 225 and thus permit shifting of the double beat valve 255 into engagement with its lower seat 268.

This time interval may be of the order of six to ten seconds and the operator, if he is on the alert, has the option of manually operating the operating handle |54 of the brake valve device 25 to an application position or, as his judgment might dictate under the circumstances, of operating the operating handle 3l5 of the acknowledging valve device 4| to acknowledging position to suppress a train control application.

Let it be assumed that the operator chooses to eiiect a service application of the brakes within the time interval permitted by the timing valve mechanism 34, and that he accordingly operates the operating handle |54 of the brake Valve device 25 to service position.

A straight-air application of the brakes is accordingly effected in the manner previously described to a degree depending upon the manner of operation of the brake valve handle |54.

Upon the supply of fluid under pressure from the rotary valve chamber |43 through the port 584 in the lower rotary valve |48 of the brake valve 25 to the passage |83 and suppression pipe |96 leading to the suppression valve device 31, the pressure established in the chamber 3 "l of the suppression Valve device overcomes the tension of the spring 22 and the diaphragm SI5 is accordingly shifted to the right-hand direction to shift the double beat valve 354 away from the valve seat 3|3 and cause it to seat on the valve seat 3M. Thus, when the pressure in the chamber 25| and timing reservoir No. 2 is reduced suiliciently so that the piston 259 is shifted downwardly into engagement with the gasket seat 215 and the double beat valve 256 is shifted into engagement with the lower valve seat 268, the communication through which liuid undery pressure would otherwise be vented from the piston chamber 6l of the application valve device I6 and the connected volume reservoir 'il to the stop reservoir 355 by way of the passage and pipe 258 and suppression valve device 3l is cut off at the seat 3|4 of the double beat valve 304. Consequently, the reduction in the pressure in the piston chamber 5l of the application valve device l5 is insuilcient to cause shifting of the piston 55 and the slide valve '1| operated thereby out of the normal position shown in Fig. 2.

Depending upon the degree of the straight-air application of the brakes, the piston 55 and slide valve il of the application valve device I5 may or may not thereafter remain in the normal position shown. If the degree of brake cylinder pressure established by the straight-air application of 'the brakes is in excess of a certain uniform pressure such as forty pounds per square inch, the pressure of the fluid supplied'from the double check valve device Si! through the pipe and passage |23 to the inner seated area of the piston Valve HB during the straight-air application of the brakes unseats the piston valve ||8 from the annular rib seat or bushing |25 against the force or. tension of the spring |2| of the insuring valve device 55 and shifts the piston valve in the right-hand direction into seated relation on the gasket seat |35. Accordingly, passage and pipe |29 is cut off from the atmospheric port and passage |32 at the insuring valve device 55 and fluid under pressure is ksupplied from the pipe and passage |23 through the chamber |25, choke passage |21', annular chamber |25, through the pipe and passage |29 which, in the straightair position oi the rotary valve ita of the changeover valve device 26, is connected by cavity 2 l@ in the rotary valve |55 to the passage |82 leading 

